Nothing in C++ is thread-safe¹ unless explicitly noted.
If you need to read object
c while it may be modified in another thread, you are responsible for locking it. That is a general rule and there is no reason why reading it for purpose of creating a copy should be an exception.
Note, that the copy being created does not need to be locked, because no other thread knows about it yet. Only the source needs to be.
The compiler does not guarantee anything to be thread-safe on it's own, because 99.9% of things don't need to be thread-safe. Most things only need to be reentrant³. So in the rare case you actually need to make something thread-safe, you have to use locks (
std::mutex) or atomic types (
You can also simply make your objects constant and then you can read them without locking, because nothing is writing them after creation. Code using constant objects is both more easily parallelised and more easily understood in general, because there is fewer things with state you have to track.
Note that on the most common architecture the
mov instruction with
int operands happens to be thread-safe. On other CPU types even that might not be true. And because the compiler is allowed to preload values, integer assignment in C++ is not anyway.
¹A set of operations is considered thread-safe if calling them concurrently on the same object is well defined². In C++, calling any modifying operation and any other operation concurrently on the same object is a data race, which is UndefinedBehaviour™.
²It is important to note, that if an object is "thread-safe", it does not really help you much most of the time anyway. Because if an object guarantees that when it's concurrently written you'll always read the new or the old value (C++ allows that when an
int c is being changed from
1000 by one thread, another thread may read, say,
232), most of the time that won't help you, because you need to read multiple values in a consistent state, for which you have to lock over them yourself anyway.
³Reentrant means that the same operation may be called on different objects at the same time. There are a few functions in standard C library that are not reentrant, because they use global (static) buffers or other state. Most have reentrant variants (with
_r suffix, usually) and the standrd C++ library uses these, so the C++ part is generally reentrant.